Download PD233: Design of Biomedical Devices and Systems

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Cardiac contractility modulation wikipedia , lookup

Electrocardiography wikipedia , lookup

Transcript
PD233: Design of
Biomedical Devices and
Systems
(Lecture-7 Biopotentials 2)
Dr. Manish Arora
CPDM, IISc
Course Website:
http://cpdm.iisc.ac.in/utsaah/courses/
Electromyogram (EMG)
Skeletal muscles are organized
functionally on basis of motor unit
Motor unit is smallest unit that can be
by activated by volitional effort and all
muscle fibers in that unit are activated
synchronously.
In a single firing of motor unit
extracellular field 20-2000μV for
duration of 3-15ms.
Frequency of discharge varies from 6-30
per second.
Image source: Mosby's Medical Dictionary, 8th edition
Normal EMG with increasing
effort
Zennaro D, et al. IEEE Trans Biomed Eng, 50(1):58–69, 2003
Anatomy and Function of Heart
Heart in humans is four chambered pump of circulatory system.
Filling phase : Diastole
Active/contractile phase: Systole
Well coordinated electrical activity leads smooth rhythmic contractions of
atria and ventricles
Image Source: Wikimedia.org
Electrical activity of heart
Heart muscles have resting potential of about -90mV
During electrical systole heart muscles first rapidly depolarized (at 150V/s) and then
gradually repolarize over 200-300ms
This depolarization and repolarization happens in spatially co-ordinated manner
ECG measurements (3 lead
system)
I = LA - RA
II = LL - RA
III = LL - LA
Three lead configuration uses three surface electrodes:
Note: Leads do not mean electrodes –
Lead refers voltage difference between two electrodes
Three lead configuration gives component of polarization vector in the vertical
(coronal plane)
ECG measurements (other leads)
Wilsons terminal: Vw= (RA+LA+LL)/3
Augmented limb leads
aVR= 2/3(RA- Vw)
aVL= 2/3(LA- Vw)
aVF= 2/3(LL- Vw)
V1-V6 are precordial lead which give
projection polarization vector in horizontal
plane
Wilsons terminal is used as negative
electrodes for precordial leads.
Normal and Abnormal Heart
Rhythms
Bradycardia : slow down on heart rate (e.g. during
sleep)
Tachycardia : faster than normal heart rate (e.g. due
to exercise, emotions or fever)
Complete Heart Block: electrical activity does not
pass to ventricles (Problem with bundle of His)
First degree Heart Block: longer transmission time to
ventricles, P-R interval in prolonged
Second Degree Heart Block: not all atrial pulse are
conducted
Normal and Abnormal Heart
Rhythms
Ectopic focus: A portion of myocardium node is irritable
and can ‘fire’ independently.
Paroxymal Tachycardia
Atrial Flutter
Atrial fibrillation
Ventricular Fibrillation
Myocardial Infarction (MI): Blood flow stops to part of
the cardiac muscle.
Electroretinogram (ERG)
Rod and Cone are specialized
(photosensitive) nerve cells
present in the Retina
Contact Lens
Electrode
Reference
Electrode
ERG
Temporal changes in potential
between retina and reference
location in response to
exposure to light.
Electro-oclulogram (EOG)
• Steady potential
between retina and
cornea (i.e. DC
measurement)
• Can be used for eye
gaze tracking –
horizontal and verticle
• Linear relationship
between angle of gaze
and EOG
Image credit : http://www.oculist.net
Electroencephalogram (EEG)
In the nervous system
information is transmitted
using frequency modulated
impulse.
EEG measures potential
fluctuations recorded from
the brain.
Parietal
Lobe
Frontal
Lobe
Temporal
Lobe
EEG can be recorded using
• scalp electrodes
• cortical electrodes
• depth electrodes
Main parts of the brain
Image credit: CRUK
Occipital
Lobe
Resting EEG
Cortical or depth EEG recording can be as large as 10mV but scalp
EEG recoding are order 100μV, and are result of synchronous action
of a region in the brain.
Resting stage EEG is divided into:
Alpha 8-13 Hz
(Relaxation)
Beta 14-30 Hz (up to 50Hz)
(Alertness and tension)
Theta 4-7Hz
(REM dreaming sleep)
Delta below 3.5Hz
(Deep sleep)
Evoked Reponses Potentials (ERP)
EEG response can be gathered in response to certain
stimuli, e.g.
Auditory evoked response (AER)
-Response to clicks (100μs) and tones (100ms
pulses) can be used to check auditory circuit of the brain.
Visual evoked response (VER)
-Reponses to visual stimuli
Cognition potentials
-Response to cognitive function (recognising
known object, odd sound etc.)
10-20 electrode system
Standardized system for EEG Electrode placement.
Epilepsy
Neurological disease
characterized by seizures
Convulsive seizures occur in
60% of the cases, but 40%
cases may not have show
convulsion.
EEG is used as tool to
characterized Epilepsy
Abnormal EEG patters in Epilepsy
• Generalized
• Partial
• Focal
Electrode-electrolyte interface
Biopotenatial electrodes are
also transducers
• they convert ionics currents
to electron flow in the lead
wires.
The electrochemistry of
electrode materials governs
their characteristics
Types of electrodes:
• Polarizable electrodes
(noble metals, Au, Pt)
• Non-polarizable electrode
(Ag/AgCl)
Webster, Medical Instrumentation, Chapter 5
Floating
electrodes
Equivalent circuit of electrode
Ehc = Half cell potential
Rd , Cd = impedances associated with electrodeelectrolyte systems
Rs = Series resistance
Flexible electrodes
Webster, Medical Instrumentation, Chapter 5
Needle electrodes
Webster, Medical Instrumentation, Chapter 4
Foetal Electrode
Microelectrode Arrays
Microfabricated electrode array
Effect of Polarization of Electrical
Stimulation
Constanta Voltage Stimulation
Constanta Current Stimulation
Biopotential Amplifiers
Requirements
• High input impedance
• Input protection
• High Gain
• Differential Input
• High Common Mode Rejection
• Calibration possibility
Electrocardiogram (ECG)
Webster, Medical Instrumentation, Chapter 6
Electrical Interference
Power Line Pickup
Myogenic interference
Interference voltage
Shielding of cable
Lower skin-electrode
Impedance
Common mode interference
Driven Right Leg
Other Biopotential Amplifier
Webster, Medical Instrumentation, Chapter 6